“Enhanced Impact Resistance of Three-Dimensional-Printed Parts with Structured Filaments”
ACS Applied Materials & Interfaces
Robots that can build homes, marathoners’ running shoes and NASA’s upcoming spacecraft all have one thing in common: 3-D printed parts. But as enthusiasm for 3-D printing continues to grow and expand across markets, the objects printed by the process can have weaknesses. Now, one group reports in ACS Applied Materials & Interfaces that using a simple modification to the manufacture of the starting materials improves the toughness of these printable plastics.
As the 3-D printing market not only expands but also becomes more affordable, it is finding applications in many different areas. But this versatility is limited by the strength and durability of the printed parts. Most of these objects are printed in layers, which inherently results in weak spots where the layers meet. Thus, 3-D printed objects are not as strong as those made with current methods in which plastics are injected into molds. To create stronger 3-D printed parts, Miko Cakmak, Bryan D. Vogt and colleagues wanted to explore whether the starting materials could be changed to self-reinforce the printed parts.
The researchers made a structured, core-shell polymer filament in which a polycarbonate core acts as a stiff skeleton to support and reinforce the 3-D printed shape. An olefin ionomer shell around the polycarbonate core improves and strengthens the connection between the printed layers. During testing, printed parts with the filaments could withstand impacts without cracking, unlike parts made without them. The new filaments bring 3-D printed parts closer to the strength of parts manufactured by current methods.
The authors acknowledge funding from the University of Akron.
Note: ACS does not conduct research, but publishes and publicizes peer-reviewed scientific studies.